Glycosphingolipid patterns of fetal and adult small intestinal mucosa in the sheep

The ganglioside and neutral glycosphingolipid composition of fetal and adult sheep small intestinal mucosa were characterized and compared. Mono- and tetrahexosylceramide were the major neutral glycolipids of both fetal and adult tissue. Fetal mucosa, however, possessed a higher content of monohexosylceramide than its adult counterpart. Similarly, G_D1a, G_M3 and G_M2 were found to be the principal gangliosides in fetal and adult tissue. Adult intestinal mucosa possessed significant amounts of G_T1a not present in fetal tissue. Analysis of the hydroxy and nonhydroxy fatty acids as well as the long-chain bases of the major glycosphingolipids revealed differences between these lipophilic components of glycolipids in fetal and adult intestinal mucosa. The results, therefore, indicate that both quantitative and qualitative differences in glycosphingolipid composition exist between fetal and adult sheep small intestinal mucosa.     

EFFECT OF LIGHT ON GANGLIOSIDES FROM CALF RETINA AND PHOTORECEPTORS

—The gangliosides of the whole calf retina and the rod outer segments have been analysed. This has been done in two functional states: before and after stimulation by light. After exposure to light no statistically significant change in the gangliosides of the whole retina was observed, but a 40 per cent increase in concentration was found in the rod outer segments. This difference was apparent only when using the same batch of rod outer segments. The major ganglioside in the whole calf retina is G_D3 which accounts for 46 per cent of the total. Three other gangliosides G_D1a, G_D1b and G_T1 are quantitatively important, each being between 12 and 16 per cent. G_Q1, G_M1, and G_M3 are minor constituents. In contrast to the chicken retina, G_M2 was not detected. The ganglioside N-acetylneuraminic acid of the rod outer segments accounts for only 1 per cent of the gangliosides of the whole retina. The composition of the gangliosides in the rod outer segments is essentially the same as that of the whole retina. No difference in the relative proportion of the gangliosides of either the rod outer segments or the whole retina was observed after exposure to light.     

CEREBRAL LIPIDS IN A CASE OF SYSTEMIC GM2-GANGLIOSIDOSIS OF A LATE INFANTILE TYPE1

—Quantitative analyses performed on the lipids of cerebral grey matter from brains of a normal child and a child with Tay-Sachs (T-S) disease were compared with such analyses on the brain of a 6-year-old, non-Jewish male with systemic G_M2-gangliosidosis of a late infantile type (G_M2-LI). Analysis of gangliosides showed a 3·5-fold increase of total gangliosides in the G_M2-LI brain and a six-fold increase in the T-S brain, compared to normal brain. Both pathological brains had similar distribution patterns for gangliosides, with the G_M2-ganglioside component constituting more than 80 per cent of the total. Lipid components in the T-S brain were below normal values except for lecithin and cholesterol, while in the G_M2-LI brain there were increases in sulphatides, cerebrosides, sphingomyelin and cholesterol. Approximately twice as much ceramide trihexoside was present in the T-S brain as in the G_M2-LI brain, and none could be detected in the normal brain. The clinical, pathological and biochemical data support the conclusion that this case represents a new variant of systemic late-infantile gangliosidosis in which there is an accumulation of the G_M2-ganglioside like that in Tay-Sachs disease.     

METABOLISM OF BRAIN SPHINGOMYELINS: HALF-LIVES OF SPHINGOSINE, FATTY ACIDS AND PHOSPHATE FROM TWO TYPES OF RAT BRAIN SPHINGOMYELIN

Abstract— The metabolism of rat brain sphingomyelins containing short-chain (C₁₆-C₁₈) and long-chain (C₂₀- C₂₄) fatty acids has been studied by determination of the content of radioactivity in the sphingo-sinc. fatty acids and phosphate of the sphingomyelins over a period of 60 days following the intracisternal injection of [¹⁴C]acetate and [³²P]phosphate. From the rate of decrease of the specific radioactivities of the different constituents of short-chain fatty acid sphingomyelins, we have calculated a half-life of 65 days for sphingosine. 41 days for fatty acids and 62 days for phosphate. For the long-chain fatty acid sphingomyelins the half-life of sphingosine was approximately 465 days. The fatty acids and phosphate from these sphingomyelins had fast and slow turnover pools. The half-life for the fast pool was 7 days for the two constituents and the estimated half-lives for the slow pool were 220 days for fatty acids and 480 days for phosphate. These results suggest that one can distinguish at least three metabolic pools of brain sphingomyelins: (a) sphingomyelins with long-chain fatty acids situated in myelin whose half-lives are 465 days for sphingosine, 220 days for fatty acids and 480 days for phosphate; (b) sphingomyelins with long-chain fatty acids located mainly in non-myelin structures having half-lives of 465 days for sphingosine. 7 days for fatty acids and 7 days for phosphate; (c) sphingomyeiins with short-chain fatty acids with half-lives of 65 days for sphingosine. 41 days for fatty acids and 62 days for phosphate. The differences between the half-lives of the three metabolic pools of sphingomyelin, together with the subcellular localizations of the two molecular species of these compounds, suggest that the metabolism of the different molecular species of sphingomyelin are independent and that in various subcellular fractions the long-chain fatty acid and short-chain fatty acid sphingomyelins have different turnover rates.     

Brain sphingoglycolipids in Krabbe's globoid cell leucodystrophy

Abstract— Seven sphingoglycolipids were isolated from the white matter of a patient with globoid cell leucodystrophy (Krabbe's disease). After purification by saponification and column and preparative thin-layer chromatography, these compounds were analysed for the carbohydrate composition and sequence and for fatty acid composition by paper and gas-liquid chromatography. The compounds were identified as gluco- and galactocerebrosides, lactosyl-ceramide, digalactosy I-glucosyl-ceramide, two types of tetrahexosyl-ceramides (asialo-ganglioside and globoside), and sulphatide. Glucocerebrosideconstituted 13 percent of total cerebroside in white matter, but sulphatide contained only galactose. Galactocere-broside and sulphatide exhibited compositions of fatty acids similar to those in normal white matter, with only minor abnormalities. Other sphingoglycolipids showed fatty acid patterns with relatively high proportions of longer-chain fatty acids, rather than the predominant C_18:0 acid usually found in ceramide hexosides of the brain. Hematoside, also found in the white matter in a significant amount, similarly contained a large proportion of longer-chain fatty acids, whereas other gangliosides contained predominantly C_18:0 acid. The abnormal ceramide hexoside pattern was restricted mostly to white matter except for glucocerebroside, which constituted 32 per cent of grey matter cerebroside. We postulate that the visceral type of sphingoglycolipids may be constituents of globoid cells, abundantly present in white matter and considered to be cells of mesenchymal origin.     

THE EFFECT OF CARBON DIOXIDE TENSION ON THE METABOLISM OF CEREBRAL CORTEX AND MEDULLA OBLONGATA

Manometric measurements were made of oxygen uptake (Q _OO2) and aerobic lactic acid output (Q_G) by slices of cerebral cortex and medulla oblongata of the cat in the presence of mixtures of 1, 5, and 20 volumes per cent of carbon dioxide in oxygen. The concentrations of NaHCO₃ and NaCl in the medium were varied to maintain constant pH and sodium ion concentrations. The calcium ion concentration was 0.0002 M. At pH 7.5 under these conditions, an increase in carbon dioxide from 1 per cent to 5 per cent doubled the Q_G of both tissues but did not alter Q _OO2; an increase from 5 per cent to 20 per cent carbon dioxide had no further effect on Q_G in either tissue or Q _OO2 of cortex, but did depress the Q _OO2 of medulla. At pH 8.1, an increase in carbon dioxide from 1 per cent to 5 per cent raised the Q _OO2 and Q_G of cortex by about 60 per cent. Measurements at low oxygen tension carried out previously in phosphate medium were repeated in bicarbonate medium to obtain data for the combined output of lactic acid and carbon dioxide (Q_A). When the oxygen in the gas phase was decreased from 95 to 3 volumes per cent, the lactic acid output as measured colorimetrically increased by 114 mg./gm. in cortex and by 8 mg./gm. in medulla; Q_A increased from 12.3 to 13.5 in cortex and decreased from 5.1 to 3.8 in medulla.     

THE BINDING OF BOTULINUM TOXIN TO MEMBRANE LIPIDS: SPHINGOLIPIDS, STEROIDS AND FATTY ACIDS

A number of lipids known to be constituents of nerve-ending membranes were tested for their ability to inactivate botulinum toxin. Inactivation of the toxin by a lipid was taken as presumptive evidence that the lipid might be the in vivo receptor for the toxin. Several sphingolipids (sphingosine, galactosylceramide, glucosylceramide, lactosylceramide, cytolipin K and cytolipin R), steroids (cholesterol and deoxycholic acid) and fatty acids (palmitic acid, stearic acid, prostaglandin E₁) did not affect the potency of botulinum toxin, and thus were discounted as potential toxin receptors. However, the gangliosides did inactivate botulinum toxin rapidly (in less than 5 min), within a temperature range of 2°-40°C, and at ionic strengths of 0.05-0.40. Inactivation diminished as pH fell below 6. The activity of gangliosides in suppressing the potency of botulinum toxin was a function of the number of sialic acid residues in the lipid. Thus, the data suggest that a molecule containing sialic acid may be the receptor for the toxin.     

STALOSYLGALACTOSYL CERAMTDE AS A SPECIFIC MARKER FOR HUMAN MYELIN AND OLIGODENDROGLIAL PERIKARYA: GANGLIOSIDES OF HUMAN MYELIN, OLIGODENDROGLIA AND NEURONS

Gangliosides were isolated from human brain myelin, oligodendroglia, and neurons. Quantitative analysis revealed the following ganglioside contents: myelin, 2.0; neurons, 1.3; and oligodendroglia, 0.35 μg ganglioside sialic acid per mg protein. Myclin had a relatively simple ganglioside pattern with G_M4 and G_M1 as the predominant ganglioside species. The ganglioside pattern of oligodendroglia was quite complex and it resembled that of whole white matter rather than that of myelin. A high concentration of G_M4 was found in oligodendroglial fractions in addition to G_M1, G_D1a, G_D1b, and G_T1b. The usually- minor brain gangliosides G_M3, G_M2, and G_M3 were also enriched in oligodendroglia. The neuronal ganglioside pattern was generally similar to the pattern of whole gray matter. Both neurons and whole gray matter contained very low amounts of G_M4. These results indicate that G_M4 is specifically localized in myelin and oligodendroglia of the CNS. Evidence is also presented that myelin, but not oligodendroglia, is the major reservoir of human white matter G_M1 and G_M4.     

High-performance thin-layer chromatography and densitometric determination of brain ganglioside compositions of several species.

Improved resolution of complex brain ganglioside mixtures was achieved by high-performance thin-layer chromatography. The percentage distribution of individual gangliosides was then determined by direct densitometric seanning, employing a transmittance mode, of the resorcinol-positive spots on the plate. As little as 90 pmol (29 ng) of lipid-bound sialic acid could be detected with a good signal-to-noise ratio. A linear detector response was observed up to 3.0 μg of lipid-bound sialic acid. The brain white matter ganglioside patterns of eight animal species, including human, chimpanzee, monkey, chicken, bovine, sheep, and pig, were examined in detail. In addition, human brain gray matter, rat cerebral, rat brain gray matter, and rat cerebellar ganglioside patterns were also studied. Ganglioside G_M4 (G₇) was found to be one of the major components in primate and chicken brain white matter, but it represented only a minor ganglioside in other species. Other major gangliosides in all brain samples studied were G_M1, G_D1a, G_D1b, and G_T1b. G_M1 was more abundant in white matter than in gray matter. G_T1a, a recently discovered ganglioside species, was found in all species examined, but was most abundant in the rat cerebellum. The latter source also contained high proportions of G_T1b and G_Q1b.     

Fatty acids and long-chain bases of gangliosides of human gastrointestinal mucosa

The fatty acid and long-chain base composition of five major gangliosides from human stomach and small and large intestine mucosa were analyzed with gas chromatography. All the gangliosides greatly resembled each other in the fatty acid pattern. The main fatty acids were C_16:0, C_18:0 and C_24:0. No hydroxy fatty acids could be detected. In all the gangliosides 4-sphingenine was the predominant long-chain base (70–75%). About 15% of the long-chain bases had 20 carbon atoms in their chain. No trihydroxy long-chain bases could be detected.     

GLYCOSPHINGOLIPIDS IN FETAL TAY-SACHS DISEASE BRAIN AND LUNG CULTURES

Abstract— A study was undertaken of the glycosphingolipids in cell cultures derived from cerebellum of Tay-Sachs disease fetal brain in order to determine the suitability of such cell strains as a model for Tay-Sachs disease. The glycosphingolipids in the Tay-Sachs disease cultured cerebellar cells were compared with those found in normal cultured cerebellar cells, normal and Tay-Sachs cultured lung cells, and normal and Tay-Sachs fetal brain. The glycolipids were separated by TLC, then analyzed by GLC of the trimethylsilyi derivatives of the methylglycosides of the sugar moieties. In the cultured cerebellar lines, the predominant gangliosides were G_M2, G_M3, and G_D3. There was a 4-fold increase of G_M2 in the Tay-Sachs as compared with the normal line. Only G_M3 and G_D3 gangliosides were found in the Tay-Sachs and the normal fetal lung cell cultures. The major neutral glycosphingolipids in all of the cultured cells which were analyzed were glucosylceramide, lactosylceramide, digalactosyl-glucosylceramide, and globoside. When the Tay-Sachs cerebellar cells were labelled with [1-¹⁴C]gluco-samine, some radioactivity was observed in the trihexosylceramide band, indicating the presence of a small amount of a galactosamine-containing trihexosylceramide which may be asialo-G_M2 (G_A2). The trihexosylceramide in Tay-Sachs fetal brain was identified as G_A2 by GLC. Both Tay-Sachs and normal fetal brain gangliosides were more complex than those found in the cultured cells. Long chain fatty acids (C_24:0 and C_24;1) predominated in all of the glycosphingolipids of the Tay-Sachs and the normal cultured cerebellar cells. In contrast, the glycosphingolipids of Tay-Sachs and normal fetal brain contained mainly the shorter chain fatty acids (C₁₆:₀, C₁₈:₀, and C_18:1). The cerebrosides in both the Tay-Sachs and normal fetal brains were mainly glucosylceramide with only small amounts of the galactosylceramide which predominates in infant brain. Cultured cells from the fetal Tay-Sachs disease     

Fatty acid composition of cholesterol esters in brains of patients with Schilder's disease, G M1 -gangliosidosis and Tay-Sachs disease, and its possible relationship to the -position fatty acids of lecithin

Abstract— Cholesterol esters were isolated from cerebral cortex and white matter of patients with Schilder's disease, G_M1-gangliosidosis and Tay-Sachs disease, and the fatty acid composition was determined by gas-liquid chromatography. The fatty acid composition was similar among the three pathological conditions, but it was entirely different from that reported for cholesterol esters of normal brain. Lecithin and ethanolamine phospholipids were isolated from the same brain specimens, treated with snake venom phospholipase A, and the fatty acids at the a’and β-positions of the glycerol moiety were determined separately. The fatty acid composition of cholesterol esters was similar to that of the β-position fatty acids of lecithin of white matter in all samples, and was quite different from those of the a'-position of lecithin, or of the a’or β-position of ethanolamine phospholipids. The results indicate that the source of fatty acids for cholesterol esterification in nonspecific sudanophilic demyelination is different from that in normal brain, and that the most likely source is the β-linked fatty acids of lecithin. There are two possible enzymic mechanisms; activation of phospholipase A and subsequent esterification of the liberated β-position fatty acids to cholesterol, or direct transacylation by lecithin-cholesterol acyl transferase.     

COMPARISON OF THE FATTY ACIDS OF LIPIDS OF SUBCELLULAR BRAIN FRACTIONS

Abstract— Rat brain grey and white matter were fractionated to yield myelin, nerve terminal, synaptic vesicle, nerve terminal 'ghost', and microsomal fractions of white and grey matter. Ester-type glycolipids were found in all fractions except myelin, while cerebrosides occurred in significant concentrations only in myelin and white microsomes. Comparison of the fatty acid profile of the ethanolamine- and serine-containing phospholipids showed marked differences between myelin and the particles from grey matter, while the microsomes of white matter were of intermediate composition. Docosahexaenoic acid, a minor acid in myelin, was a major fatty acid in microsomes of grey and white matter. The fatty acid composition of sphingomyelin was distinctly different in the fractions derived from grey and white matter, clustering about stearate and nervonate in the latter, but only about stearate in the grey. Marked differences in the positional distribution of fatty acids were seen within phosphatidyl choline from myelin and nerve terminals. Ribonucleic acid was found in nerve terminal and synaptic vesicle fractions. The sphingosine found in the ganglioside from microsomes of both grey and white matter was similar with respect to distribution of the C₁₈ and C₂₀ homologues.
The possibility is discussed that microsomes furnish characteristic lipids for the synthesis or renewal of specific membranes, and that these lipids are accumulated somewhat before being released.     

Concentration and fatty acid composition of cholesteryl esters of normal human brain

Abstract— —Cholesteryl esters were isolated from the cerebral cortex and white matter of human brains at different ages, and their concentration and composition determined. The esters were separated from other lipids by chromatography on silicic acid and finally purified by TLC. The fatty acids were converted to the methyl esters by alkaline trans-methylation and analysed by GLC. A TLC method was elaborated for quantitative determination of small amounts of cholesteryl esters in the presence of free cholesterol. The concentration of cholesteryl esters was only 0·1–0·2 per cent of the total cholesterol content of cerebral tissue in older children and adults. During early myelination the concentration was many times greater, especially in the white matter but it never exceeded 2 per cent of the total cholesterol in any subject. The major fatty acids of human brain cholesteryl esters were oleic, palmitic, palmitoleic and arachidonic acid. After completion of myelination, arachidonic acid constituted the major fatty acid. There were fairly small differences in the fatty acid pattern of the cholesteryl esters between grey and white matter, but the concentration of polyunsaturated fatty acids was larger in the grey matter. Cholesteryl esters appear to play an important role in the metabolism of the phosphoglyceride fatty acids in cerebral tissue.     

GANGLIOSIDES OF HUMAN MYELIN: SIALOSYLGALACTOSYLCERAMIDE (G7) AS A MAJOR COMPONENT

Abstract— Gangliosides were isolated from purified human myelin in a yield of 62 μg of lipid-bound sialic acid per 100 mg of dry myelin. Sialosylgalactosyl ceramide (G₇) was found to be a major component of the ganglioside fraction, amounting to 15 per cent of the total sialic acid. It accounted for 10 per cent of lipid-bound sialic acid in adult human white matter, making it the third most abundant ganglioside on a molar basis. These results were obtained with an improved method for isolating total gangliosides in high yield, by employing DEAE-Sephadex column chromatography. Myelin from other mammalian species had considerably less G₇, and there were also indications of maturational changes. Both 2-hydroxy and unsubstituted fatty acids were components of the ceramide unit, in a ratio of 3:2, respectively. The overall fatty acid pattern was very similar to that for myelin cerebroside and sulphatide. Long-chain bases included only C₁₈ species, with sphingosine predominating (>90 per cent). These observations suggest a metabolic relationship between G₇ and either cerebroside or sulphatide.     

Neurological Mutation Characterized by Dysmyelination in NCTR-Balb/C Mouse with Lysosomal Lipid Storage Disease

Abstract: Morphological and biochemical studies were performed on the CNS of neurologically affected NCTR Balb/C mouse. Histological and electron microscopic techniques demonstrated severe myelin deficiency in the affected brains. Neither the presence of lipid-containing macrophages nor reactive gliosis was apparent. Analysis of myelin-associated lipids and proteins revealed prominent depletion of galactocerebroside, sulfatide, and proteolipid proteins. In contrast to the scarcity of myelin specific constituents a marked accumulation of G_M2 and G_M3 gangliosides and several neutral glycolipids, i.e., glucocerebroside, lactosylceramide, gangliotriaosylceramide, and gangliotetraosylceramide were found in affected CNS. These abnormalities were already apparent in 12-day-old pups as well as in 65-day-old mice. A significant deficit in the proportion of long-chain fatty acids (C₂₄), notable in both normal and α-hydroxy acids of cerebrosides from affected white matter, was measured. The lack of reactive gliosis, the observed depletion of galactocerebroside and sulfatide at the early age of 12 days, and the relative decrease in long-chain fatty acids in affected CNS strongly suggest a defect in myelinogenesis in this mutant rather than a secondary process of myelin breakdown.     

Characterization of major glycolipids in bovine erythrocyte membrane

Several neutral glycolipids and gangliosides were isolated from bovine erythrocyte stroma. Their structures were determined by partial acid hydrolysis, methylation analysis, periodate oxidation and CrO3 oxidation. Two major neutral glycolipids were characterized as lactosylceramide and galactosyl(alpha1--3)galactosyl(beta1--4)N-acetylglucosaminyl(beta1--3)galactosyl(beta1--4)glucosyl(beta1--1)ceramide. Two major gangliosides were N-glycolylneuraminosyl(2--3)galactosyl(beta1--4)glucosyl(beta1--1)ceramide and N-glycolylneuraminosyl(2--3)galactosyl(beta1--4)N-acetylglucosaminyl(beta1--3)galactosyl(beta1--4)glucosyl(beta1--1)ceramide. Minor glycolipids were glucosyl- and galactosylceramide, glucosamine-containing tri- and tetraglycosylceramide, glucosamine-containing disialosylhexaglycosylceramide, and gangliosides containing N-acetylneuraminic acid. The ceramide moiety of each glycolipid contained perdominantly d18:1 sphingosine, and normal fatty acids of C16:0, C22:0, C24:0, and C24:1.     

The lipid composition of axons from bovine brain

Abstract— Bovine axons derived from myelinated CNS axons were found to have 13.5% lipid. This lipid was composed of 20.1% cholesterol, 20.1% galactolipid, 14.6% ethanolarhine phosphatides (56.4% in the plasmalogen form), 18.3% choline phosphatides (10.0% in the plasmalogen form), 9.3% sphingomyelin, 5.6% phosphatidyl serine and 3.4% phosphatidyl inositol. The bovine axons had 0.33 μg ganglioside NeuNAc/mg dry weight. The axon gangliosides were found to contain the four major types of bovine gangliosides, as well as gangliosides G_M2 and G_D3. The latter two amounted to 20.9 and 15.8 mole per cent respectively, of total gangliosides. On a molar basis, about one half of the gangliosides were monosialogangliosides, with a decreased contribution by gangliosides G_T1 and GD_1b relative to ganglioside distributions which have been reported for most other CNS components. The relationship of the bovine axonal lipid composition to bovine white matter and its constituents, as well as to other CNS and PNS axonal preparations is discussed.     

Changes in fatty acid composition of human brain myelin lipids during maturation

Abstract— The variation with age of the fatty acid composition of the major lipids in human brain myelin was compared with that of cerebral white matter from the same region. The myelin was isolated from the semiovale centre of the cerebrum of 27 subjects neonatal to old aged. The phospholipid, cholesterol and galactolipid concentrations were determined in all the samples, as were the proportions of the major phospholipid classes. The proportions of cholesterol and especially of the galactolipids increased in myelin during the first 6 months, and in cerebral white matter up to 2 years. During this period the individual phospholipids also varied substantially. Serine phosphoglycerides and especially sphingomyelins increased, and choline phosphoglycerides decreased. The fatty acid patterns of ethanolamine phosphoglycerides (EPG) and sphingomyelins underwent the largest changes. The proportions of saturated fatty acids in EPG diminished rapidly, and there was an increase of monoenoic acids. Fatty acids of the linoleic acid series showed a peak between 4 and 12 months, after which time their proportion slowly diminished to old age. The major fatty acid of this series was docosatetraenoic acid, 22:4 (n-6), which constituted more than 25% of total fatty acids at the maximum level. The fatty acid changes were larger in cerebral white matter, but from 2 years of age the EPG fatty acid pattern in myelin was similar to that in white matter. The fatty acid changes in serine and choline phosphoglycerides of myelin with maturation were much less striking than in EPG but of a similar type. In myelin sphingomyelin the proportion of saturated long-chain fatty acids, C₁₆-C₂₂, diminished, while that of monoenoic acids increased and continued to do so up to old age. From 2 years of age the fatty acid patterns in myelin and cerebral white matter were quite similar. Also the fatty acid patterns of cerebrosides and sulphatides in cerebral white matter and myelin were the same except for the first 2 months of life. The same fatty acid changes occurred in cerebrosides and sulphatides as in the sphingomyelins, i.e. increased proportions of unsaturated (monoenoic) acids. The proportions of 24:1 and 24h:1 and of the odd-numbered fatty acids 25:1 and 23h:1 continued to increase to old age. The variations of the individual lipid fatty acid patterns were small except in the youngest age classes, in which the variations were presumably ascribable to the difficulty in determining the gestational age.     

Enzymatic sulphation of some galactose- containing sphingolipids in developing rat brain

Abstract— Cerebroside sulphotransferase has been found to catalyze the transfer of sulphate from 3′-phosphoadenosine-5′-phosphosulfate (PAPS) to both the α-hydroxy fatty acid galactosylceramides and the nonhydroxy fatty acid galactosylceramides. The sulphotransferase has a higher affinity for the α-hydroxy fatty acid galactosylceramides than for the nonhydroxy fatty acid galactosylceramides and will also use lactosylceramide as an acceptor for the transfer of sulphate from PAPS. A second sulphotransferase, PAPS: psychosine sulphotransferase, is also present in the developing rat brain and will catalyse the transfer of sulphate from PAPS to galactosylsphingosine and lactosylsphingosine. The sulphate moiety was determined to be on the galactose and most likely on the 3′ position giving a proposed structure of: 3-O-SO₄-galactosylsphingosine. The possible role of this later pathway in the synthesis of sulphogaiactosylceramide remains to be elucidated.